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Case study: command-line interface (CLI) tutorial
In psichomics: Graphical Interface for Alternative Splicing Quantification, Analysis and Visualisation
psichomics is an interactive R package for integrative analyses of alternative
splicing and gene expression based on The Cancer Genome Atlas (TCGA)
(containing molecular data associated with 34 tumour types), the
Genotype-Tissue Expression (GTEx) project (containing data for multiple
normal human tissues), Sequence Read Archive (SRA) and user-provided
data. The data from GTEx, TCGA and select SRA projects include
subject/sample-associated information and transcriptomic data, such as the
quantification of RNA-Seq reads aligning to splice junctions (henceforth called
junction quantification) and exons.
Installing and starting the program
Install psichomics by typing the following in an R console (the
R environment is required):
install.packages("BiocManager")
BiocManager::install("psichomics")
After the installation, load psichomics by typing:
library(psichomics)
Quick reference of psichomics functions
Please read the following function reference.
Exploration of clinically-relevant, differentially spliced events in breast cancer
The following case study was adapted from psichomics' original article:
Nuno Saraiva-Agostinho and Nuno L. Barbosa-Morais (2019).
psichomics: graphical application for alternative splicing quantification and analysis. Nucleic Acids Research.
Breast cancer is the cancer type with the highest incidence and mortality in
women [@Torre2015] and multiple studies have suggested that transcriptome-wide
analyses of alternative splicing changes in breast tumours are able to uncover
tumour-specific biomarkers [@Tsai2015; @DananGotthold2015; @Anczukow2015].
Given the relevance of early detection of breast cancer to patient survival, we
can use psichomics to identify novel tumour stage-I-specific molecular
signatures based on differentially spliced events.
Downloading and loading TCGA data
The quantification of each alternative splicing event is based on the proportion
of junction reads that support the inclusion isoform, known as percent
spliced-in or PSI [@wang2008].
To estimate this value for each splicing event, both alternative splicing
annotation and junction quantification are required. While alternative splicing
annotation is provided by the package, junction quantification may be retrieved
from TCGA, GTEx, SRA or user-provided files.
Data is downloaded from Firebrowse, a service that hosts processed
data from TCGA, as required to run the downstream analyses. Before
downloading data, check the following options:
# Available tumour types
cohorts <- getFirebrowseCohorts()
# Available sample dates
date <- getFirebrowseDates()
# Available data types
dataTypes <- getFirebrowseDataTypes()
Note there is also the option for Gene expression (normalised by RSEM).
However, we recommend to load the raw gene expression data instead, followed by
filtering and normalisation as demonstrated afterwards.
After deciding on the options to use, download and load breast cancer data as
follows:
# Set download folder
folder <- getDownloadsFolder()
# Download and load most recent junction quantification and clinical data from
# TCGA/Firebrowse for Breast Cancer
data <- loadFirebrowseData(folder=folder,
cohort="BRCA",
data=c("clinical", "junction_quantification",
"RSEM_genes"),
date="2016-01-28")
names(data)
names(data[[1]])
# Select clinical and junction quantification dataset
clinical <- data[[1]]$`Clinical data`
sampleInfo <- data[[1]]$`Sample metadata`
junctionQuant <- data[[1]]$`Junction quantification (Illumina HiSeq)`
geneExpr <- data[[1]]$`Gene expression`
Data is only downloaded if the files are not present in the given folder. In
other words, if the files were already downloaded, the function will just load
the files, so it is possible to reuse the code above just to load the requested
files.
Windows limitations: If you are using Windows, note that the downloaded
files have huge names that may be over Windows Maximum Path Length.
A workaround would be to manually rename the downloaded files to have shorter
names, move all downloaded files to a single folder and load such folder.
clinical <- readRDS("BRCA_clinical.RDS")
geneExpr <- readRDS("BRCA_geneExpr.RDS")
Filtering and normalising gene expression
As this package does not focuses on gene expression analysis, we suggest to read
the RNA-seq section of limma's user guide. Nevertheless, we present the
following commands to quickly filter and normalise gene expression:
# Check genes with 10 or more counts in at least some samples and 15 or more
# total counts across all samples
filter <- filterGeneExpr(geneExpr, minCounts=10, minTotalCounts=15)
# What normaliseGeneExpression() does:
# 1) Filter gene expression
# 2) Normalise gene expression with edgeR::calcNormFactors (internally) using
# the trimmed mean of M-values (TMM) method (by default)
# 3) Calculate log2-counts per million (logCPM)
geneExprNorm <- normaliseGeneExpression(geneExpr,
geneFilter=filter,
method="TMM",
log2transform=TRUE)
Quantifying alternative splicing
After loading the clinical and alternative splicing junction quantification data
from TCGA, quantify alternative splicing by clicking the green panel
Alternative splicing quantification.
As previously mentioned, alternative splicing is quantified from the previously
loaded junction quantification and an alternative splicing annotation file. To
check current annotation files available:
# Available alternative splicing annotation
annotList <- listSplicingAnnotations()
annotList
Custom splicing annotation: Additional alternative splicing annotations
can be prepared for psichomics by parsing the annotation from programs like
VAST-TOOLS, MISO, SUPPA and rMATS. Note that SUPPA and rMATS are
able to create their splicing annotation based on transcript annotation. Please
read Preparing alternative splicing annotations.
To quantify alternative splicing, first select the junction quantification,
alternative splicing annotation and alternative splicing event type(s) of
interest:
# Load Human (hg19/GRCh37 assembly) annotation
hg19 <- listSplicingAnnotations(assembly="hg19")[[1]]
annotation <- loadAnnotation(hg19)
# Available alternative splicing event types (skipped exon, alternative
# first/last exon, mutually exclusive exons, etc.)
getSplicingEventTypes()
Afterwards, quantify alternative splicing using the previously defined
parameters:
# Discard alternative splicing quantified using few reads
minReads <- 10 # default
psi <- quantifySplicing(annotation, junctionQuant, minReads=minReads)
psi <- readRDS("BRCA_psi.RDS")
sampleInfo <- parseTCGAsampleInfo(colnames(psi))
# Check the identifier of the splicing events in the resulting table
events <- rownames(psi)
head(events)
Note that the event identifier (for instance,
SE_1_-_2125078_2124414_2124284_2121220_C1orf86) is composed of:
- Event type (
SE stands for skipped exon)
- Chromosome (
1)
- Strand (
-)
- Relevant coordinates depending on event type (in this case, the first
constitutive exon's end, the alternative exon' start and end and the second
constitutive exon's start)
- Associated gene (
C1orf86)
Warning: all examples shown in this case study are performed using a
small, yet representative subset of the available data. Therefore, values shown
here may correspond to those when performing the whole analysis.
Data grouping
Let us create groups based on available samples types (i.e. Metastatic,
Primary solid Tumor and Solid Tissue Normal) and tumour stages. As tumour
stages are divided by sub-stages, we will merge sub-stages so as to have only
tumour samples from stages I, II, III and IV (stage X samples are discarded as
they are uncharacterised tumour samples).
# Group by normal and tumour samples
types <- createGroupByAttribute("Sample types", sampleInfo)
normal <- types$`Solid Tissue Normal`
tumour <- types$`Primary solid Tumor`
# Group by tumour stage (I, II, III or IV) or normal samples
stages <- createGroupByAttribute(
"patient.stage_event.pathologic_stage_tumor_stage", clinical)
groups <- list()
for (i in c("i", "ii", "iii", "iv")) {
stage <- Reduce(union,
stages[grep(sprintf("stage %s[a|b|c]{0,1}$", i), names(stages))])
# Include only tumour samples
stageTumour <- names(getSubjectFromSample(tumour, stage))
elem <- list(stageTumour)
names(elem) <- paste("Tumour Stage", toupper(i))
groups <- c(groups, elem)
}
groups <- c(groups, Normal=list(normal))
# Prepare group colours (for consistency across downstream analyses)
colours <- c("#6D1F95", "#FF152C", "#00C7BA", "#FF964F", "#00C65A")
names(colours) <- names(groups)
attr(groups, "Colour") <- colours
# Prepare normal versus tumour stage I samples
normalVSstage1Tumour <- groups[c("Tumour Stage I", "Normal")]
attr(normalVSstage1Tumour, "Colour") <- attr(groups, "Colour")
# Prepare normal versus tumour samples
normalVStumour <- list(Normal=normal, Tumour=tumour)
attr(normalVStumour, "Colour") <- c(Normal="#00C65A", Tumour="#EFE35C")
Principal component analysis (PCA)
PCA is a technique to reduce data dimensionality by identifying variable
combinations (called principal components) that explain the variance in the data
[@Ringner2008]. Use the following commands to perform PCA:
# PCA of PSI between normal and tumour stage I samples
psi_stage1Norm <- psi[ , unlist(normalVSstage1Tumour)]
pcaPSI_stage1Norm <- performPCA(t(psi_stage1Norm))
As PCA cannot be performed on data with missing values, missing values need to
be either removed (thus discarding data from whole splicing events or genes) or
impute them (i.e. attributing to missing values the median of the non-missing
ones). Use the argument missingValues of performPCA() to select the number
of missing values that are tolerable per event (i.e. if a splicing event or gene
has less than N missing values, those missing values will be imputed; otherwise,
the event is discarded from PCA).
# Explained variance across principal components
plotPCAvariance(pcaPSI_stage1Norm)
# Score plot (clinical individuals)
plotPCA(pcaPSI_stage1Norm, groups=normalVSstage1Tumour)
# Loading plot (variable contributions)
plotPCA(pcaPSI_stage1Norm, loadings=TRUE, individuals=FALSE,
nLoadings=100)
For performance reasons, the loading plot is able to limit the number of top
variables that most contribute to the select principal components, as controlled
by the argument nLoadings of plotPCA().
Hint: As most plots in psichomics, PCA plots can be zoomed-in by
clicking-and-dragging within the plot (click Reset zoom to zoom-out). To
toggle the visibility of the data series represented in the plot, click its
respective name in the plot legend.
# Table of variable contributions (as used to plot PCA, also)
table <- calculateLoadingsContribution(pcaPSI_stage1Norm)
head(table, 5)
To perform PCA using alternative splicing quantification and gene expression
data (both using all samples and only Tumour Stage I and Normal samples):
# PCA of PSI between all samples (coloured by tumour stage and normal samples)
pcaPSI_all <- performPCA(t(psi))
plotPCA(pcaPSI_all, groups=groups)
plotPCA(pcaPSI_all, loadings=TRUE, individuals=FALSE)
# PCA of gene expression between all samples (coloured by tumour stage and
# normal samples)
pcaGE_all <- performPCA(t(geneExprNorm))
plotPCA(pcaGE_all, groups=groups)
plotPCA(pcaGE_all, loadings=TRUE, individuals=FALSE)
# PCA of gene expression between normal and tumour stage I samples
ge_stage1Norm <- geneExprNorm[ , unlist(normalVSstage1Tumour)]
pcaGE_stage1Norm <- performPCA(t(ge_stage1Norm))
plotPCA(pcaGE_stage1Norm, groups=normalVSstage1Tumour)
plotPCA(pcaGE_stage1Norm, loadings=TRUE, individuals=FALSE)
NUMB exon 12 inclusion and correlation with QKI gene expression
One of the splicing events that most contribute the separation between tumour
stage I and normal samples is NUMB exon 12 inclusion, whose protein is
crucial for cell differentiation as a key regulator of the Notch pathway. The
RNA-binding protein QKI has been shown to repress NUMB exon 12 inclusion in
lung cancer cells by competing with core splicing factor SF1 for binding to the
branch-point sequence, thereby repressing the Notch signalling pathway, which
results in decreased cancer cell proliferation [@zong2014].
Differential inclusion of NUMB exon 12
Let's check whether a significant difference in NUMB exon 12 inclusion
between tumour and normal TCGA breast samples. To do so:
# Find the right event
ASevents <- rownames(psi)
(tmp <- grep("NUMB", ASevents, value=TRUE))
NUMBskippedExon12 <- tmp[1]
# Plot the representation of NUMB exon 12 inclusion
plotSplicingEvent(NUMBskippedExon12)
# Plot its PSI distribution
plotDistribution(psi[NUMBskippedExon12, ], normalVStumour)
Consistent with the cited article, NUMB exon 12 inclusion is significantly
increased in cancer.
Also of interest:
- Hover each group in the plot to compare the respective number of samples,
median and variance.
- To zoom in a specific region, click-and-drag in the region of interest.
- To hide or show groups, click on their name in the legend.
Correlation between NUMB exon 12 inclusion and QKI expression
To verify if NUMB exon 12 inclusion is correlated with QKI expression:
# Find the right gene
genes <- rownames(geneExprNorm)
(tmp <- grep("QKI", genes, value=TRUE))
QKI <- tmp[1] # "QKI|9444"
# Plot its gene expression distribution
plotDistribution(geneExprNorm[QKI, ], normalVStumour, psi=FALSE)
plotCorrelation(correlateGEandAS(
geneExprNorm, psi, QKI, NUMBskippedExon12, method="spearman"))
According to the obtained results and also consistent with the previous article,
the inclusion of the exon is negatively correlated with QKI expression.
Differential splicing analysis
To analyse alternative splicing between normal and tumour stage I samples:
diffSplicing <- diffAnalyses(psi, normalVSstage1Tumour)
# Filter based on |∆ Median PSI| > 0.1 and q-value < 0.01
deltaPSIthreshold <- abs(diffSplicing$`∆ Median`) > 0.1
pvalueThreshold <- diffSplicing$`Wilcoxon p-value (BH adjusted)` < 0.01
eventsThreshold <- diffSplicing[deltaPSIthreshold & pvalueThreshold, ]
# Plot results
library(ggplot2)
ggplot(diffSplicing, aes(`∆ Median`,
-log10(`Wilcoxon p-value (BH adjusted)`))) +
geom_point(data=eventsThreshold,
colour="orange", alpha=0.5, size=3) +
geom_point(data=diffSplicing[!deltaPSIthreshold | !pvalueThreshold, ],
colour="gray", alpha=0.5, size=3) +
theme_light(16) +
ylab("-log10(q-value)")
# Table of events that pass the thresholds
head(eventsThreshold)
Performing multiple survival analysis
To study the impact of alternative splicing events on prognosis, Kaplan-Meier
curves may be plotted for groups of patients separated by the optimal PSI
cutoff for a given alternative splicing event that that maximises the
significance of group differences in survival analysis (i.e. minimises the
p-value of the log-rank tests of difference in survival between individuals
whose samples have their PSI below and above that threshold).
Given the slow process of calculating the optimal splicing quantification
cutoff for multiple events, it is recommended to perform this for a subset of
differentially spliced events.
# Events already tested which have prognostic value
events <- c(
"SE_9_+_6486925_6492303_6492401_6493826_UHRF2",
"SE_4_-_87028376_87024397_87024339_87023185_MAPK10",
"SE_2_+_152324660_152324988_152325065_152325155_RIF1",
"SE_2_+_228205096_228217230_228217289_228220393_MFF",
"MXE_15_+_63353138_63353397_63353472_63353912_63353987_63354414_TPM1",
"SE_2_+_173362828_173366500_173366629_173368819_ITGA6",
"SE_1_+_204957934_204971724_204971876_204978685_NFASC")
# Survival curves based on optimal PSI cutoff
library(survival)
# Assign alternative splicing quantification to patients based on their samples
samples <- colnames(psi)
match <- getSubjectFromSample(samples, clinical, sampleInfo=sampleInfo)
survPlots <- list()
for (event in events) {
# Find optimal cutoff for the event
eventPSI <- assignValuePerSubject(psi[event, ], match, clinical,
samples=unlist(tumour))
opt <- optimalSurvivalCutoff(clinical, eventPSI, censoring="right",
event="days_to_death",
timeStart="days_to_death")
(optimalCutoff <- opt$par) # Optimal exon inclusion level
(optimalPvalue <- opt$value) # Respective p-value
label <- labelBasedOnCutoff(eventPSI, round(optimalCutoff, 2),
label="PSI values")
survTerms <- processSurvTerms(clinical, censoring="right",
event="days_to_death",
timeStart="days_to_death",
group=label, scale="years")
surv <- survfit(survTerms)
pvalue <- testSurvival(survTerms)
plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE)
}
Differential gene expression
Detected alterations in alternative splicing may simply be a reflection of
changes in gene expression levels. Therefore, to disentangle these two effects,
differential expression analysis between tumour stage I and normal samples
should also be performed. In order to do so:
# Prepare groups of samples to analyse and further filter unavailable samples in
# selected groups for gene expression
ge <- geneExprNorm[ , unlist(normalVSstage1Tumour), drop=FALSE]
isFromGroup1 <- colnames(ge) %in% normalVSstage1Tumour[[1]]
design <- cbind(1, ifelse(isFromGroup1, 0, 1))
# Fit a gene-wise linear model based on selected groups
library(limma)
fit <- lmFit(ge, design)
# Calculate moderated t-statistics and DE log-odds using limma::eBayes
ebayesFit <- eBayes(fit, trend=TRUE)
# Prepare data summary
pvalueAdjust <- "BH" # Benjamini-Hochberg p-value adjustment (FDR)
summary <- topTable(ebayesFit, number=nrow(fit), coef=2, sort.by="none",
adjust.method=pvalueAdjust, confint=TRUE)
names(summary) <- c("log2 Fold-Change", "CI (low)", "CI (high)",
"Average expression", "moderated t-statistics", "p-value",
paste0("p-value (", pvalueAdjust, " adjusted)"),
"B-statistics")
attr(summary, "groups") <- normalVSstage1Tumour
# Calculate basic statistics
stats <- diffAnalyses(ge, normalVSstage1Tumour, "basicStats",
pvalueAdjust=NULL)
final <- cbind(stats, summary)
# Differential gene expression between breast tumour stage I and normal samples
library(ggplot2)
library(ggrepel)
cognateGenes <- unlist(parseSplicingEvent(events)$gene)
logFCthreshold <- abs(final$`log2 Fold-Change`) > 1
pvalueThreshold <- final$`p-value (BH adjusted)` < 0.01
final$genes <- gsub("\\|.*$", "\\1", rownames(final))
ggplot(final, aes(`log2 Fold-Change`,
-log10(`p-value (BH adjusted)`))) +
geom_point(data=final[logFCthreshold & pvalueThreshold, ],
colour="orange", alpha=0.5, size=3) +
geom_point(data=final[!logFCthreshold | !pvalueThreshold, ],
colour="gray", alpha=0.5, size=3) +
geom_text_repel(data=final[cognateGenes, ], aes(label=genes),
box.padding=0.4, size=5) +
theme_light(16) +
ylab("-log10(q-value)")
UHRF2 exon 10 inclusion
One splicing event with prognostic value is the alternative splicing of UHRF2
exon 10. Cell-cycle regulator UHRF2 promotes cell proliferation and inhibits the
expression of tumour suppressors in breast cancer [@wu2012].
Differential splicing analysis
Let's check whether a significant difference in UHRF2 exon 10 inclusion
between tumour stage I and normal samples. To do so:
# UHRF2 skipped exon 10's PSI values per tumour stage I and normal samples
UHRF2skippedExon10 <- events[1]
plotDistribution(psi[UHRF2skippedExon10, ], normalVSstage1Tumour)
Higher inclusion of UHRF2 exon 10 is associated with normal samples.
Survival analysis
To study the impact of alternative splicing events on prognosis, Kaplan-Meier
curves may be plotted for groups of patients separated by a given PSI
cutoff for a given alternative splicing event. The optimal PSI cutoff
maximises the significance of group differences in survival analysis (i.e.
minimises the p-value of the log-rank tests of difference in survival between
individuals whose samples have a PSI below and above that threshold).
# Find optimal cutoff for the event
UHRF2skippedExon10 <- events[1]
eventPSI <- assignValuePerSubject(psi[UHRF2skippedExon10, ], match, clinical,
samples=unlist(tumour))
opt <- optimalSurvivalCutoff(clinical, eventPSI, censoring="right",
event="days_to_death", timeStart="days_to_death")
(optimalCutoff <- opt$par) # Optimal exon inclusion level
(optimalPvalue <- opt$value) # Respective p-value
label <- labelBasedOnCutoff(eventPSI, round(optimalCutoff, 2),
label="PSI values")
survTerms <- processSurvTerms(clinical, censoring="right",
event="days_to_death", timeStart="days_to_death",
group=label, scale="years")
surv <- survfit(survTerms)
pvalue <- testSurvival(survTerms)
plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE)
As per the results, higher inclusion of UHRF2 exon 10 is associated with
better prognosis.
Differential expression
To check whether alternative splicing changes are related with gene expression
alterations, let us perform differential expression analysis on UHRF2:
plotDistribution(geneExprNorm["UHRF2", ], normalVSstage1Tumour)
It seems UHRF2 is differentially expressed between Tumour Stage I and
Solid Tissue Normal. However, going back to exploratory differential gene
expression, UHRF2 has a log2(fold-change) ≤ 1, low enough not to be
biologically relevant. Following this criterium, the gene can thus be considered
not to be differentially expressed between these conditions.
Survival analysis
To confirm if gene expression has an overall prognostic value, perform the
following:
UHRF2ge <- assignValuePerSubject(geneExprNorm["UHRF2", ], match, clinical,
samples=unlist(tumour))
# Survival curves based on optimal gene expression cutoff
opt <- optimalSurvivalCutoff(clinical, UHRF2ge, censoring="right",
event="days_to_death", timeStart="days_to_death")
(optimalCutoff <- opt$par) # Optimal exon inclusion level
(optimalPvalue <- opt$value) # Respective p-value
# Process again after rounding the cutoff
roundedCutoff <- round(optimalCutoff, 2)
label <- labelBasedOnCutoff(UHRF2ge, roundedCutoff, label="Gene expression")
survTerms <- processSurvTerms(clinical, censoring="right",
event="days_to_death", timeStart="days_to_death",
group=label, scale="years")
surv <- survfit(survTerms)
pvalue <- testSurvival(survTerms)
plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE)
There seems to be no significant difference in survival between patient groups
stratified by UHRF2's optimal gene expression cutoff in tumour samples (log-rank
p-value > 0.05).
Literature support and external database information
If an event is differentially spliced and has an impact on patient survival,
its association with the studied disease might be already described in the
literature. To check so, go to Analyses >
Gene, transcript and protein information where information regarding the
associated gene (such as description and genomic position), transcripts and
protein domain annotation are available.
- The protein plot shows the UniProt matches for the selected transcript. Hover
the protein's rendered domains to obtain more information on them. More
information about each protein can be retrieved by clicking the respective
UniProt link.
- Links to related research articles are also available. Click Show more
articles to be directed to PubMed.
- Multiple links to related external databases are available too:
- Human Protein Atlas (Cancer Atlas) allows to check the evidence of a
gene at protein level for multiple cancer tissues.
- VastDB shows multi-species alternative splicing profiles for diverse
tissues and cell types.
- UCSC Genome Browser may reveal protein domain disruptions caused by
the alternative splicing event. To check so, activate the Pfam in UCSC
Gene and UniProt tracks (in Genes and Gene Predictions) and check if
any domains are annotated in the alternative and/or constitutive exons of
the splicing event.
Interpretation
Higher inclusion of UHRF2 exon 10 is associated with normal samples and better
prognosis, and potentially disrupts UHRF2's SRA-YDG protein domain, related to
the binding affinity to epigenetic marks. Hence, exon 10 inclusion may suppress
UHRF2's oncogenic role in breast cancer by impairing its activity through the
induction of a truncated protein or a non-coding isoform. Moreover, this
hypothesis is independent from gene expression changes, as UHRF2 is not
differentially expressed between tumour stage I and normal samples
(|log2(fold-change)| < 1) and there is no significant difference in survival
between patient groups stratified by its expression in tumour samples (log-rank
p-value > 0.05).
Loading data from other sources
Load GTEx data
GTEx data (subject phenotype, sample attributes, gene expression and junction
quantification) for specific tissues can be automatically retrieved and loaded
by following these commands:
# Check GTEx tissues available based on the sample attributes
getGtexTissues(sampleAttr)
tissues <- c("blood", "brain")
gtex <- loadGtexData("~/Downloads", tissues=tissues)
names(gtex)
names(gtex[[1]])
To load data for all GTEx tissues, please type:
gtex <- loadGtexData("~/Downloads", tissues=NULL)
names(gtex)
names(gtex[[1]])
Load SRA project data using recount
recount is a resource of pre-processed data for thousands of SRA
projects (including gene read counts, splice junction quantification and sample
metadata). psichomics supports automatic downloading and loading of SRA data
from recount, as exemplified below:
library(recount)
View(recount_abstract)
sra <- loadSRAproject("SRP053101")
names(sra)
names(sra[[1]])
Please refer to our methods article for more information (the code for
performing the analysis can be found at GitHub):
Nuno Saraiva-Agostinho and Nuno L. Barbosa-Morais (2020).
Interactive Alternative Splicing Analysis of Human Stem Cells Using psichomics. In: Kidder B. (eds) Stem Cell Transcriptional Networks. Methods in Molecular Biology, vol 2117. Humana, New York, NY
Load other SRA, VAST-TOOLS and user-provided data
Any FASTQ files can be manually aligned using a splice-aware aligner and
loaded by following the instructions in
Loading SRA, VAST-TOOLS and user-provided RNA-seq data.
Local files can be loaded by indicating their containing folder. Any files
located in this folder and sub-folders will be loaded.
For instance, to load GTEx data via local files, create a directory called
GTEx, put all GTEx files within that folder and type these commands:
folder <- "~/Downloads/GTEx/"
ignore <- c(".aux.", ".mage-tab.") # File patterns to ignore
data <- loadLocalFiles(folder, ignore=ignore)[[1]]
names(data)
names(data[[1]])
# Select clinical and junction quantification dataset
clinical <- data[["Clinical data"]]
sampleInfo <- data[["Sample metadata"]]
geneExpr <- data[["Gene expression"]]
junctionQuant <- data[["Junction quantification"]]
Feedback
All feedback on the program, documentation and associated material (including
this tutorial) is welcome. Please send any suggestions and comments to:
Nuno Saraiva-Agostinho (nunoagostinho@medicina.ulisboa.pt)
Disease Transcriptomics Lab, Instituto de Medicina Molecular (Portugal)
References
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psichomics is an interactive R package for integrative analyses of alternative splicing and gene expression based on The Cancer Genome Atlas (TCGA) (containing molecular data associated with 34 tumour types), the Genotype-Tissue Expression (GTEx) project (containing data for multiple normal human tissues), Sequence Read Archive (SRA) and user-provided data. The data from GTEx, TCGA and select SRA projects include subject/sample-associated information and transcriptomic data, such as the quantification of RNA-Seq reads aligning to splice junctions (henceforth called junction quantification) and exons.
Installing and starting the program
Install psichomics by typing the following in an R console (the R environment is required):
install.packages("BiocManager") BiocManager::install("psichomics")
After the installation, load psichomics by typing:
library(psichomics)
Quick reference of psichomics functions
Please read the following function reference.
Exploration of clinically-relevant, differentially spliced events in breast cancer
The following case study was adapted from psichomics' original article:
Nuno Saraiva-Agostinho and Nuno L. Barbosa-Morais (2019). psichomics: graphical application for alternative splicing quantification and analysis. Nucleic Acids Research.
Breast cancer is the cancer type with the highest incidence and mortality in women [@Torre2015] and multiple studies have suggested that transcriptome-wide analyses of alternative splicing changes in breast tumours are able to uncover tumour-specific biomarkers [@Tsai2015; @DananGotthold2015; @Anczukow2015]. Given the relevance of early detection of breast cancer to patient survival, we can use psichomics to identify novel tumour stage-I-specific molecular signatures based on differentially spliced events.
Downloading and loading TCGA data
The quantification of each alternative splicing event is based on the proportion of junction reads that support the inclusion isoform, known as percent spliced-in or PSI [@wang2008].
To estimate this value for each splicing event, both alternative splicing annotation and junction quantification are required. While alternative splicing annotation is provided by the package, junction quantification may be retrieved from TCGA, GTEx, SRA or user-provided files.
Data is downloaded from Firebrowse, a service that hosts processed data from TCGA, as required to run the downstream analyses. Before downloading data, check the following options:
# Available tumour types cohorts <- getFirebrowseCohorts() # Available sample dates date <- getFirebrowseDates() # Available data types dataTypes <- getFirebrowseDataTypes()
Note there is also the option for Gene expression (normalised by RSEM). However, we recommend to load the raw gene expression data instead, followed by filtering and normalisation as demonstrated afterwards.
After deciding on the options to use, download and load breast cancer data as follows:
# Set download folder folder <- getDownloadsFolder() # Download and load most recent junction quantification and clinical data from # TCGA/Firebrowse for Breast Cancer data <- loadFirebrowseData(folder=folder, cohort="BRCA", data=c("clinical", "junction_quantification", "RSEM_genes"), date="2016-01-28") names(data) names(data[[1]]) # Select clinical and junction quantification dataset clinical <- data[[1]]$`Clinical data` sampleInfo <- data[[1]]$`Sample metadata` junctionQuant <- data[[1]]$`Junction quantification (Illumina HiSeq)` geneExpr <- data[[1]]$`Gene expression`
Data is only downloaded if the files are not present in the given folder. In other words, if the files were already downloaded, the function will just load the files, so it is possible to reuse the code above just to load the requested files.
Windows limitations: If you are using Windows, note that the downloaded files have huge names that may be over Windows Maximum Path Length. A workaround would be to manually rename the downloaded files to have shorter names, move all downloaded files to a single folder and load such folder.
clinical <- readRDS("BRCA_clinical.RDS") geneExpr <- readRDS("BRCA_geneExpr.RDS")
Filtering and normalising gene expression
As this package does not focuses on gene expression analysis, we suggest to read
the RNA-seq section of limma's user guide. Nevertheless, we present the
following commands to quickly filter and normalise gene expression:
# Check genes with 10 or more counts in at least some samples and 15 or more # total counts across all samples filter <- filterGeneExpr(geneExpr, minCounts=10, minTotalCounts=15) # What normaliseGeneExpression() does: # 1) Filter gene expression # 2) Normalise gene expression with edgeR::calcNormFactors (internally) using # the trimmed mean of M-values (TMM) method (by default) # 3) Calculate log2-counts per million (logCPM) geneExprNorm <- normaliseGeneExpression(geneExpr, geneFilter=filter, method="TMM", log2transform=TRUE)
Quantifying alternative splicing
After loading the clinical and alternative splicing junction quantification data from TCGA, quantify alternative splicing by clicking the green panel Alternative splicing quantification.
As previously mentioned, alternative splicing is quantified from the previously loaded junction quantification and an alternative splicing annotation file. To check current annotation files available:
# Available alternative splicing annotation annotList <- listSplicingAnnotations() annotList
Custom splicing annotation: Additional alternative splicing annotations can be prepared for psichomics by parsing the annotation from programs like VAST-TOOLS, MISO, SUPPA and rMATS. Note that SUPPA and rMATS are able to create their splicing annotation based on transcript annotation. Please read Preparing alternative splicing annotations.
To quantify alternative splicing, first select the junction quantification, alternative splicing annotation and alternative splicing event type(s) of interest:
# Load Human (hg19/GRCh37 assembly) annotation hg19 <- listSplicingAnnotations(assembly="hg19")[[1]] annotation <- loadAnnotation(hg19)
# Available alternative splicing event types (skipped exon, alternative # first/last exon, mutually exclusive exons, etc.) getSplicingEventTypes()
Afterwards, quantify alternative splicing using the previously defined parameters:
# Discard alternative splicing quantified using few reads minReads <- 10 # default psi <- quantifySplicing(annotation, junctionQuant, minReads=minReads)
psi <- readRDS("BRCA_psi.RDS") sampleInfo <- parseTCGAsampleInfo(colnames(psi))
# Check the identifier of the splicing events in the resulting table events <- rownames(psi) head(events)
Note that the event identifier (for instance,
SE_1_-_2125078_2124414_2124284_2121220_C1orf86) is composed of:
- Event type (
SEstands for skipped exon) - Chromosome (
1) - Strand (
-) - Relevant coordinates depending on event type (in this case, the first constitutive exon's end, the alternative exon' start and end and the second constitutive exon's start)
- Associated gene (
C1orf86)
Warning: all examples shown in this case study are performed using a small, yet representative subset of the available data. Therefore, values shown here may correspond to those when performing the whole analysis.
Data grouping
Let us create groups based on available samples types (i.e. Metastatic, Primary solid Tumor and Solid Tissue Normal) and tumour stages. As tumour stages are divided by sub-stages, we will merge sub-stages so as to have only tumour samples from stages I, II, III and IV (stage X samples are discarded as they are uncharacterised tumour samples).
# Group by normal and tumour samples types <- createGroupByAttribute("Sample types", sampleInfo) normal <- types$`Solid Tissue Normal` tumour <- types$`Primary solid Tumor` # Group by tumour stage (I, II, III or IV) or normal samples stages <- createGroupByAttribute( "patient.stage_event.pathologic_stage_tumor_stage", clinical) groups <- list() for (i in c("i", "ii", "iii", "iv")) { stage <- Reduce(union, stages[grep(sprintf("stage %s[a|b|c]{0,1}$", i), names(stages))]) # Include only tumour samples stageTumour <- names(getSubjectFromSample(tumour, stage)) elem <- list(stageTumour) names(elem) <- paste("Tumour Stage", toupper(i)) groups <- c(groups, elem) } groups <- c(groups, Normal=list(normal)) # Prepare group colours (for consistency across downstream analyses) colours <- c("#6D1F95", "#FF152C", "#00C7BA", "#FF964F", "#00C65A") names(colours) <- names(groups) attr(groups, "Colour") <- colours # Prepare normal versus tumour stage I samples normalVSstage1Tumour <- groups[c("Tumour Stage I", "Normal")] attr(normalVSstage1Tumour, "Colour") <- attr(groups, "Colour") # Prepare normal versus tumour samples normalVStumour <- list(Normal=normal, Tumour=tumour) attr(normalVStumour, "Colour") <- c(Normal="#00C65A", Tumour="#EFE35C")
Principal component analysis (PCA)
PCA is a technique to reduce data dimensionality by identifying variable combinations (called principal components) that explain the variance in the data [@Ringner2008]. Use the following commands to perform PCA:
# PCA of PSI between normal and tumour stage I samples psi_stage1Norm <- psi[ , unlist(normalVSstage1Tumour)] pcaPSI_stage1Norm <- performPCA(t(psi_stage1Norm))
As PCA cannot be performed on data with missing values, missing values need to be either removed (thus discarding data from whole splicing events or genes) or impute them (i.e. attributing to missing values the median of the non-missing ones). Use the argument
missingValuesofperformPCA()to select the number of missing values that are tolerable per event (i.e. if a splicing event or gene has less than N missing values, those missing values will be imputed; otherwise, the event is discarded from PCA).
# Explained variance across principal components plotPCAvariance(pcaPSI_stage1Norm) # Score plot (clinical individuals) plotPCA(pcaPSI_stage1Norm, groups=normalVSstage1Tumour) # Loading plot (variable contributions) plotPCA(pcaPSI_stage1Norm, loadings=TRUE, individuals=FALSE, nLoadings=100)
For performance reasons, the loading plot is able to limit the number of top variables that most contribute to the select principal components, as controlled by the argument
nLoadingsofplotPCA().Hint: As most plots in psichomics, PCA plots can be zoomed-in by clicking-and-dragging within the plot (click Reset zoom to zoom-out). To toggle the visibility of the data series represented in the plot, click its respective name in the plot legend.
# Table of variable contributions (as used to plot PCA, also) table <- calculateLoadingsContribution(pcaPSI_stage1Norm) head(table, 5)
To perform PCA using alternative splicing quantification and gene expression data (both using all samples and only Tumour Stage I and Normal samples):
# PCA of PSI between all samples (coloured by tumour stage and normal samples) pcaPSI_all <- performPCA(t(psi)) plotPCA(pcaPSI_all, groups=groups) plotPCA(pcaPSI_all, loadings=TRUE, individuals=FALSE) # PCA of gene expression between all samples (coloured by tumour stage and # normal samples) pcaGE_all <- performPCA(t(geneExprNorm)) plotPCA(pcaGE_all, groups=groups) plotPCA(pcaGE_all, loadings=TRUE, individuals=FALSE) # PCA of gene expression between normal and tumour stage I samples ge_stage1Norm <- geneExprNorm[ , unlist(normalVSstage1Tumour)] pcaGE_stage1Norm <- performPCA(t(ge_stage1Norm)) plotPCA(pcaGE_stage1Norm, groups=normalVSstage1Tumour) plotPCA(pcaGE_stage1Norm, loadings=TRUE, individuals=FALSE)
NUMB exon 12 inclusion and correlation with QKI gene expression
One of the splicing events that most contribute the separation between tumour stage I and normal samples is NUMB exon 12 inclusion, whose protein is crucial for cell differentiation as a key regulator of the Notch pathway. The RNA-binding protein QKI has been shown to repress NUMB exon 12 inclusion in lung cancer cells by competing with core splicing factor SF1 for binding to the branch-point sequence, thereby repressing the Notch signalling pathway, which results in decreased cancer cell proliferation [@zong2014].
Differential inclusion of NUMB exon 12
Let's check whether a significant difference in NUMB exon 12 inclusion between tumour and normal TCGA breast samples. To do so:
# Find the right event ASevents <- rownames(psi) (tmp <- grep("NUMB", ASevents, value=TRUE)) NUMBskippedExon12 <- tmp[1] # Plot the representation of NUMB exon 12 inclusion plotSplicingEvent(NUMBskippedExon12) # Plot its PSI distribution plotDistribution(psi[NUMBskippedExon12, ], normalVStumour)
Consistent with the cited article, NUMB exon 12 inclusion is significantly increased in cancer.
Also of interest:
- Hover each group in the plot to compare the respective number of samples, median and variance.
- To zoom in a specific region, click-and-drag in the region of interest.
- To hide or show groups, click on their name in the legend.
Correlation between NUMB exon 12 inclusion and QKI expression
To verify if NUMB exon 12 inclusion is correlated with QKI expression:
# Find the right gene genes <- rownames(geneExprNorm) (tmp <- grep("QKI", genes, value=TRUE)) QKI <- tmp[1] # "QKI|9444" # Plot its gene expression distribution plotDistribution(geneExprNorm[QKI, ], normalVStumour, psi=FALSE) plotCorrelation(correlateGEandAS( geneExprNorm, psi, QKI, NUMBskippedExon12, method="spearman"))
According to the obtained results and also consistent with the previous article, the inclusion of the exon is negatively correlated with QKI expression.
Differential splicing analysis
To analyse alternative splicing between normal and tumour stage I samples:
diffSplicing <- diffAnalyses(psi, normalVSstage1Tumour) # Filter based on |∆ Median PSI| > 0.1 and q-value < 0.01 deltaPSIthreshold <- abs(diffSplicing$`∆ Median`) > 0.1 pvalueThreshold <- diffSplicing$`Wilcoxon p-value (BH adjusted)` < 0.01 eventsThreshold <- diffSplicing[deltaPSIthreshold & pvalueThreshold, ] # Plot results library(ggplot2) ggplot(diffSplicing, aes(`∆ Median`, -log10(`Wilcoxon p-value (BH adjusted)`))) + geom_point(data=eventsThreshold, colour="orange", alpha=0.5, size=3) + geom_point(data=diffSplicing[!deltaPSIthreshold | !pvalueThreshold, ], colour="gray", alpha=0.5, size=3) + theme_light(16) + ylab("-log10(q-value)") # Table of events that pass the thresholds head(eventsThreshold)
Performing multiple survival analysis
To study the impact of alternative splicing events on prognosis, Kaplan-Meier curves may be plotted for groups of patients separated by the optimal PSI cutoff for a given alternative splicing event that that maximises the significance of group differences in survival analysis (i.e. minimises the p-value of the log-rank tests of difference in survival between individuals whose samples have their PSI below and above that threshold).
Given the slow process of calculating the optimal splicing quantification cutoff for multiple events, it is recommended to perform this for a subset of differentially spliced events.
# Events already tested which have prognostic value events <- c( "SE_9_+_6486925_6492303_6492401_6493826_UHRF2", "SE_4_-_87028376_87024397_87024339_87023185_MAPK10", "SE_2_+_152324660_152324988_152325065_152325155_RIF1", "SE_2_+_228205096_228217230_228217289_228220393_MFF", "MXE_15_+_63353138_63353397_63353472_63353912_63353987_63354414_TPM1", "SE_2_+_173362828_173366500_173366629_173368819_ITGA6", "SE_1_+_204957934_204971724_204971876_204978685_NFASC") # Survival curves based on optimal PSI cutoff library(survival) # Assign alternative splicing quantification to patients based on their samples samples <- colnames(psi) match <- getSubjectFromSample(samples, clinical, sampleInfo=sampleInfo) survPlots <- list() for (event in events) { # Find optimal cutoff for the event eventPSI <- assignValuePerSubject(psi[event, ], match, clinical, samples=unlist(tumour)) opt <- optimalSurvivalCutoff(clinical, eventPSI, censoring="right", event="days_to_death", timeStart="days_to_death") (optimalCutoff <- opt$par) # Optimal exon inclusion level (optimalPvalue <- opt$value) # Respective p-value label <- labelBasedOnCutoff(eventPSI, round(optimalCutoff, 2), label="PSI values") survTerms <- processSurvTerms(clinical, censoring="right", event="days_to_death", timeStart="days_to_death", group=label, scale="years") surv <- survfit(survTerms) pvalue <- testSurvival(survTerms) plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE) }
Differential gene expression
Detected alterations in alternative splicing may simply be a reflection of changes in gene expression levels. Therefore, to disentangle these two effects, differential expression analysis between tumour stage I and normal samples should also be performed. In order to do so:
# Prepare groups of samples to analyse and further filter unavailable samples in # selected groups for gene expression ge <- geneExprNorm[ , unlist(normalVSstage1Tumour), drop=FALSE] isFromGroup1 <- colnames(ge) %in% normalVSstage1Tumour[[1]] design <- cbind(1, ifelse(isFromGroup1, 0, 1)) # Fit a gene-wise linear model based on selected groups library(limma) fit <- lmFit(ge, design) # Calculate moderated t-statistics and DE log-odds using limma::eBayes ebayesFit <- eBayes(fit, trend=TRUE) # Prepare data summary pvalueAdjust <- "BH" # Benjamini-Hochberg p-value adjustment (FDR) summary <- topTable(ebayesFit, number=nrow(fit), coef=2, sort.by="none", adjust.method=pvalueAdjust, confint=TRUE) names(summary) <- c("log2 Fold-Change", "CI (low)", "CI (high)", "Average expression", "moderated t-statistics", "p-value", paste0("p-value (", pvalueAdjust, " adjusted)"), "B-statistics") attr(summary, "groups") <- normalVSstage1Tumour # Calculate basic statistics stats <- diffAnalyses(ge, normalVSstage1Tumour, "basicStats", pvalueAdjust=NULL) final <- cbind(stats, summary) # Differential gene expression between breast tumour stage I and normal samples library(ggplot2) library(ggrepel) cognateGenes <- unlist(parseSplicingEvent(events)$gene) logFCthreshold <- abs(final$`log2 Fold-Change`) > 1 pvalueThreshold <- final$`p-value (BH adjusted)` < 0.01 final$genes <- gsub("\\|.*$", "\\1", rownames(final)) ggplot(final, aes(`log2 Fold-Change`, -log10(`p-value (BH adjusted)`))) + geom_point(data=final[logFCthreshold & pvalueThreshold, ], colour="orange", alpha=0.5, size=3) + geom_point(data=final[!logFCthreshold | !pvalueThreshold, ], colour="gray", alpha=0.5, size=3) + geom_text_repel(data=final[cognateGenes, ], aes(label=genes), box.padding=0.4, size=5) + theme_light(16) + ylab("-log10(q-value)")
UHRF2 exon 10 inclusion
One splicing event with prognostic value is the alternative splicing of UHRF2 exon 10. Cell-cycle regulator UHRF2 promotes cell proliferation and inhibits the expression of tumour suppressors in breast cancer [@wu2012].
Differential splicing analysis
Let's check whether a significant difference in UHRF2 exon 10 inclusion between tumour stage I and normal samples. To do so:
# UHRF2 skipped exon 10's PSI values per tumour stage I and normal samples UHRF2skippedExon10 <- events[1] plotDistribution(psi[UHRF2skippedExon10, ], normalVSstage1Tumour)
Higher inclusion of UHRF2 exon 10 is associated with normal samples.
Survival analysis
To study the impact of alternative splicing events on prognosis, Kaplan-Meier curves may be plotted for groups of patients separated by a given PSI cutoff for a given alternative splicing event. The optimal PSI cutoff maximises the significance of group differences in survival analysis (i.e. minimises the p-value of the log-rank tests of difference in survival between individuals whose samples have a PSI below and above that threshold).
# Find optimal cutoff for the event UHRF2skippedExon10 <- events[1] eventPSI <- assignValuePerSubject(psi[UHRF2skippedExon10, ], match, clinical, samples=unlist(tumour)) opt <- optimalSurvivalCutoff(clinical, eventPSI, censoring="right", event="days_to_death", timeStart="days_to_death") (optimalCutoff <- opt$par) # Optimal exon inclusion level (optimalPvalue <- opt$value) # Respective p-value label <- labelBasedOnCutoff(eventPSI, round(optimalCutoff, 2), label="PSI values") survTerms <- processSurvTerms(clinical, censoring="right", event="days_to_death", timeStart="days_to_death", group=label, scale="years") surv <- survfit(survTerms) pvalue <- testSurvival(survTerms) plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE)
As per the results, higher inclusion of UHRF2 exon 10 is associated with better prognosis.
Differential expression
To check whether alternative splicing changes are related with gene expression alterations, let us perform differential expression analysis on UHRF2:
plotDistribution(geneExprNorm["UHRF2", ], normalVSstage1Tumour)
It seems UHRF2 is differentially expressed between Tumour Stage I and Solid Tissue Normal. However, going back to exploratory differential gene expression, UHRF2 has a log2(fold-change) ≤ 1, low enough not to be biologically relevant. Following this criterium, the gene can thus be considered not to be differentially expressed between these conditions.
Survival analysis
To confirm if gene expression has an overall prognostic value, perform the following:
UHRF2ge <- assignValuePerSubject(geneExprNorm["UHRF2", ], match, clinical, samples=unlist(tumour)) # Survival curves based on optimal gene expression cutoff opt <- optimalSurvivalCutoff(clinical, UHRF2ge, censoring="right", event="days_to_death", timeStart="days_to_death") (optimalCutoff <- opt$par) # Optimal exon inclusion level (optimalPvalue <- opt$value) # Respective p-value # Process again after rounding the cutoff roundedCutoff <- round(optimalCutoff, 2) label <- labelBasedOnCutoff(UHRF2ge, roundedCutoff, label="Gene expression") survTerms <- processSurvTerms(clinical, censoring="right", event="days_to_death", timeStart="days_to_death", group=label, scale="years") surv <- survfit(survTerms) pvalue <- testSurvival(survTerms) plotSurvivalCurves(surv, pvalue=pvalue, mark=FALSE)
There seems to be no significant difference in survival between patient groups stratified by UHRF2's optimal gene expression cutoff in tumour samples (log-rank p-value > 0.05).
Literature support and external database information
If an event is differentially spliced and has an impact on patient survival, its association with the studied disease might be already described in the literature. To check so, go to Analyses > Gene, transcript and protein information where information regarding the associated gene (such as description and genomic position), transcripts and protein domain annotation are available.
- The protein plot shows the UniProt matches for the selected transcript. Hover the protein's rendered domains to obtain more information on them. More information about each protein can be retrieved by clicking the respective UniProt link.
- Links to related research articles are also available. Click Show more articles to be directed to PubMed.
- Multiple links to related external databases are available too:
- Human Protein Atlas (Cancer Atlas) allows to check the evidence of a gene at protein level for multiple cancer tissues.
- VastDB shows multi-species alternative splicing profiles for diverse tissues and cell types.
- UCSC Genome Browser may reveal protein domain disruptions caused by the alternative splicing event. To check so, activate the Pfam in UCSC Gene and UniProt tracks (in Genes and Gene Predictions) and check if any domains are annotated in the alternative and/or constitutive exons of the splicing event.
Interpretation
Higher inclusion of UHRF2 exon 10 is associated with normal samples and better prognosis, and potentially disrupts UHRF2's SRA-YDG protein domain, related to the binding affinity to epigenetic marks. Hence, exon 10 inclusion may suppress UHRF2's oncogenic role in breast cancer by impairing its activity through the induction of a truncated protein or a non-coding isoform. Moreover, this hypothesis is independent from gene expression changes, as UHRF2 is not differentially expressed between tumour stage I and normal samples (|log2(fold-change)| < 1) and there is no significant difference in survival between patient groups stratified by its expression in tumour samples (log-rank p-value > 0.05).
Loading data from other sources
Load GTEx data
GTEx data (subject phenotype, sample attributes, gene expression and junction quantification) for specific tissues can be automatically retrieved and loaded by following these commands:
# Check GTEx tissues available based on the sample attributes getGtexTissues(sampleAttr) tissues <- c("blood", "brain") gtex <- loadGtexData("~/Downloads", tissues=tissues) names(gtex) names(gtex[[1]])
To load data for all GTEx tissues, please type:
gtex <- loadGtexData("~/Downloads", tissues=NULL) names(gtex) names(gtex[[1]])
Load SRA project data using recount
recount is a resource of pre-processed data for thousands of SRA projects (including gene read counts, splice junction quantification and sample metadata). psichomics supports automatic downloading and loading of SRA data from recount, as exemplified below:
library(recount) View(recount_abstract) sra <- loadSRAproject("SRP053101") names(sra) names(sra[[1]])
Please refer to our methods article for more information (the code for performing the analysis can be found at GitHub):
Nuno Saraiva-Agostinho and Nuno L. Barbosa-Morais (2020). Interactive Alternative Splicing Analysis of Human Stem Cells Using psichomics. In: Kidder B. (eds) Stem Cell Transcriptional Networks. Methods in Molecular Biology, vol 2117. Humana, New York, NY
Load other SRA, VAST-TOOLS and user-provided data
Any FASTQ files can be manually aligned using a splice-aware aligner and loaded by following the instructions in Loading SRA, VAST-TOOLS and user-provided RNA-seq data.
Local files can be loaded by indicating their containing folder. Any files located in this folder and sub-folders will be loaded.
For instance, to load GTEx data via local files, create a directory called GTEx, put all GTEx files within that folder and type these commands:
folder <- "~/Downloads/GTEx/" ignore <- c(".aux.", ".mage-tab.") # File patterns to ignore data <- loadLocalFiles(folder, ignore=ignore)[[1]] names(data) names(data[[1]]) # Select clinical and junction quantification dataset clinical <- data[["Clinical data"]] sampleInfo <- data[["Sample metadata"]] geneExpr <- data[["Gene expression"]] junctionQuant <- data[["Junction quantification"]]
Feedback
All feedback on the program, documentation and associated material (including this tutorial) is welcome. Please send any suggestions and comments to:
Nuno Saraiva-Agostinho (nunoagostinho@medicina.ulisboa.pt)
Disease Transcriptomics Lab, Instituto de Medicina Molecular (Portugal)
References
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